Mn+1AXn –phases (MAX-phase materials) are ternary compounds consisting of an early transition metal (M), such as Ti or V, a p-element from group III-V (A) and C and/or N (X). The phases have a layered structure in which the A element form planes separated by MX slabs. This nanolaminated atomic arrangement gives rise to a unique set of properties. These properties in combination with a good match in thermal expansion between substrate and coating make MAX-phase materials challenging materials to extend the lifetime of thermal barrier coatings. Evaluation of properties of HVOF sprayed MAX-phase materials and to compare these properties with commercially used bond coat materials such as MCrAlY coatings is thus of great interest which was the aim of this study.
The non-linear load displacement relationships and Young’s modulus for HVOF-sprayed Ti2AlC coatings and APS
sprayed NiCoCrAlY coatings onto Hastalloy X substrates were determined using data from both Berkovich and
spherical microindentation. Results between Berkovich and spherical microindentation measurements are compared
and discussed.

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BibTeX @conference{Fasth2009,author={Fasth, Angelica and Nylén, Per and Choi, Brian and Klement, Uta},title={A comparative study of mechanical properties between HVOF-sprayed Maxphase materials},booktitle={Proceedings of the 22nd International Conference on Surface Modification Techniques},isbn={978-0-9817065-1-1},pages={149-156},abstract={Mn+1AXn –phases (MAX-phase materials) are ternary compounds consisting of an early transition metal (M), such as Ti or V, a p-element from group III-V (A) and C and/or N (X). The phases have a layered structure in which the A element form planes separated by MX slabs. This nanolaminated atomic arrangement gives rise to a unique set of properties. These properties in combination with a good match in thermal expansion between substrate and coating make MAX-phase materials challenging materials to extend the lifetime of thermal barrier coatings. Evaluation of properties of HVOF sprayed MAX-phase materials and to compare these properties with commercially used bond coat materials such as MCrAlY coatings is thus of great interest which was the aim of this study.
The non-linear load displacement relationships and Young’s modulus for HVOF-sprayed Ti2AlC coatings and APS
sprayed NiCoCrAlY coatings onto Hastalloy X substrates were determined using data from both Berkovich and
spherical microindentation. Results between Berkovich and spherical microindentation measurements are compared
and discussed.},year={2009},keywords={MAX-phase, HVOF, APS, thermal spraying, microindentation, Young's modulus},}

RefWorks RT Conference ProceedingsSR PrintID 85927A1 Fasth, AngelicaA1 Nylén, PerA1 Choi, BrianA1 Klement, UtaT1 A comparative study of mechanical properties between HVOF-sprayed Maxphase materialsYR 2009T2 Proceedings of the 22nd International Conference on Surface Modification TechniquesSN 978-0-9817065-1-1SP 149OP 156AB Mn+1AXn –phases (MAX-phase materials) are ternary compounds consisting of an early transition metal (M), such as Ti or V, a p-element from group III-V (A) and C and/or N (X). The phases have a layered structure in which the A element form planes separated by MX slabs. This nanolaminated atomic arrangement gives rise to a unique set of properties. These properties in combination with a good match in thermal expansion between substrate and coating make MAX-phase materials challenging materials to extend the lifetime of thermal barrier coatings. Evaluation of properties of HVOF sprayed MAX-phase materials and to compare these properties with commercially used bond coat materials such as MCrAlY coatings is thus of great interest which was the aim of this study.
The non-linear load displacement relationships and Young’s modulus for HVOF-sprayed Ti2AlC coatings and APS
sprayed NiCoCrAlY coatings onto Hastalloy X substrates were determined using data from both Berkovich and
spherical microindentation. Results between Berkovich and spherical microindentation measurements are compared
and discussed.LA engOL 30